TY - CHAP
T1 - Shortcuts to Adiabaticity
AU - Torrontegui, Erik
AU - Ibáñez, Sara
AU - Martínez-Garaot, Sofia
AU - Modugno, Michele
AU - del Campo, Adolfo
AU - Guéry-Odelin, David
AU - Ruschhaupt, Andreas
AU - Chen, Xi
AU - Muga, Juan Gonzalo
PY - 2013
Y1 - 2013
N2 - Quantum adiabatic processes-that keep constant the populations in the instantaneous eigenbasis of a time-dependent Hamiltonian-are very useful to prepare and manipulate states, but take typically a long time. This is often problematic because decoherence and noise may spoil the desired final state, or because some applications require many repetitions. "Shortcuts to adiabaticity" are alternative fast processes which reproduce the same final populations, or even the same final state, as the adiabatic process in a finite, shorter time. Since adiabatic processes are ubiquitous, the shortcuts span a broad range of applications in atomic, molecular, and optical physics, such as fast transport of ions or neutral atoms, internal population control, and state preparation (for nuclear magnetic resonance or quantum information), cold atom expansions and other manipulations, cooling cycles, wavepacket splitting, and many-body state engineering or correlations microscopy. Shortcuts are also relevant to clarify fundamental questions such as a precise quantification of the third principle of thermodynamics and quantum speed limits. We review different theoretical techniques proposed to engineer the shortcuts, the experimental results, and the prospects.
AB - Quantum adiabatic processes-that keep constant the populations in the instantaneous eigenbasis of a time-dependent Hamiltonian-are very useful to prepare and manipulate states, but take typically a long time. This is often problematic because decoherence and noise may spoil the desired final state, or because some applications require many repetitions. "Shortcuts to adiabaticity" are alternative fast processes which reproduce the same final populations, or even the same final state, as the adiabatic process in a finite, shorter time. Since adiabatic processes are ubiquitous, the shortcuts span a broad range of applications in atomic, molecular, and optical physics, such as fast transport of ions or neutral atoms, internal population control, and state preparation (for nuclear magnetic resonance or quantum information), cold atom expansions and other manipulations, cooling cycles, wavepacket splitting, and many-body state engineering or correlations microscopy. Shortcuts are also relevant to clarify fundamental questions such as a precise quantification of the third principle of thermodynamics and quantum speed limits. We review different theoretical techniques proposed to engineer the shortcuts, the experimental results, and the prospects.
KW - Adiabatic dynamics
KW - Fast expansions
KW - Quantum speed limits
KW - Quantum state engineering
KW - Superadiabaticity
KW - Third principle of thermodynamics
KW - Transitionless tracking algorithm
KW - Transport engineering of cold atoms
KW - Transport of Bose-Einstein condensates
KW - Transport of cold ions
KW - Wavepacket splitting
UR - https://www.scopus.com/pages/publications/84880740810
U2 - 10.1016/B978-0-12-408090-4.00002-5
DO - 10.1016/B978-0-12-408090-4.00002-5
M3 - Chapter
AN - SCOPUS:84880740810
T3 - Advances in Atomic, Molecular and Optical Physics
SP - 117
EP - 169
BT - Advances in Atomic, Molecular and Optical Physics
PB - Academic Press Inc.
ER -